Melina Schadt, Niklas Herrmann, Claudia Formen, Christian Simons, Elisabeth Heine, Felix Jakob, Ulrich Schwaneberg* and Andreas Herrmann*,
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引用次数: 0
Abstract
Textile processing has had a negative impact on the environment in past decades, e.g., due to the usage of toxic chemicals and high amounts of contaminated wastewater. Therefore, the demand for bio-based and eco-friendly textile processing has strongly increased in the past few years. Polyethylene terephthalate (PET) is the most commonly used polymer in the clothing and technical textile sectors due to its excellent chemical and physical properties (e.g., low weight while being mechanically durable). However, its intrinsic hydrophobicity requires harsh pretreatment and processing before being fully usable as a product in the field of clothing and sportswear. To overcome these issues, we present a protein-based finish that improves the hydrophilicity of PET fabrics, thus improving the comfortability and suitability of PET fibers in sportswear. Fusion proteins consisting of a material binding anchor peptide (AP) and a functional moiety consisting of supercharged unfolded polypeptides (SUPs) were genetically engineered. The protein was produced in an easy, one-step, and scalable recombinant expression. Functionalization of PET with the AP-SUP fusion protein was achieved through dip coating in aqueous solution at room temperature, offering an energy efficient and resource saving textile finishing process that is compatible with existing machinery in the textile finishing industry. We successfully demonstrated that our ultrathin AP-SUP finish hydrophilized the textile surface, improved moisture management, and remained on the PET surface after washing.
过去几十年来,纺织加工对环境产生了负面影响,例如,由于使用有毒化学品和大量废水受到污染。因此,在过去几年中,对生物基和生态友好型纺织品加工的需求急剧增加。聚对苯二甲酸乙二醇酯(PET)因其优异的化学和物理性能(如重量轻、机械耐用),成为服装和技术纺织品领域最常用的聚合物。然而,由于其固有的疏水性,在完全用作服装和运动服领域的产品之前,需要对其进行苛刻的预处理和加工。为了克服这些问题,我们提出了一种基于蛋白质的整理剂,可改善 PET 织物的亲水性,从而提高 PET 纤维在运动服装中的舒适性和适用性。融合蛋白由材料结合锚肽(AP)和超电荷未折叠多肽(SUP)组成的功能分子经基因工程改造而成。这种蛋白质是通过简单、一步到位和可扩展的重组表达方式生产出来的。通过在室温水溶液中进行浸涂,实现了 AP-SUP 融合蛋白对 PET 的功能化,提供了一种节能、节省资源的纺织品整理工艺,与纺织品整理行业的现有机械设备兼容。我们成功地证明了我们的超薄 AP-SUP 后整理剂能亲水纺织品表面,改善湿度管理,并在洗涤后仍保留在 PET 表面。
期刊介绍:
ACS Applied Engineering Materials is an international and interdisciplinary forum devoted to original research covering all aspects of engineered materials complementing the ACS Applied Materials portfolio. Papers that describe theory simulation modeling or machine learning assisted design of materials and that provide new insights into engineering applications are welcomed. The journal also considers experimental research that includes novel methods of preparing characterizing and evaluating new materials designed for timely applications. With its focus on innovative applications ACS Applied Engineering Materials also complements and expands the scope of existing ACS publications that focus on materials science discovery including Biomacromolecules Chemistry of Materials Crystal Growth & Design Industrial & Engineering Chemistry Research Inorganic Chemistry Langmuir and Macromolecules.The scope of ACS Applied Engineering Materials includes high quality research of an applied nature that integrates knowledge in materials science engineering physics mechanics and chemistry.
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